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| United States Patent |
6,089,549
|
|
Ingram
, et al.
|
July 18, 2000
|
Exchange column structured packing bed having packing bricks
Abstract
A plurality of structured packing bricks are positioned in a column having
a longitudinal axis to form one or more structured packing beds. Each
brick is formed from a plurality of corrugated plates disposed in parallel
relation and having opposed ends that form end surfaces of the bricks. At
least one end surface, and normally both end surfaces, of the bricks are
inclined at an angle to the column axis so each brick has an end surface
that engages and overlaps the inclined end surface of a horizontally
adjacent brick. The inclined end surfaces include openings formed by the
plate corrugations and, due to the overlapping positioning of adjacent end
surfaces, liquid is able to flow vertically downwardly from openings in
one brick end surface into openings in the adjacent brick end surface.
These angle end surfaces also disrupt the vertical flow of vapor so that
vertical channeling of vapor along the end surfaces is disrupted. The
shape of the packing bricks can include trapezoidal and parallelogram.
| Inventors:
|
Ingram; Lonnie L. (Braman, OK);
Nigg; Jason M. (Wichita, KS);
Yeoman; Neil (Merrick, NY)
|
| Assignee:
|
Koch-Glitsch, Inc. (Wichita, KS)
|
| Appl. No.:
|
936878 |
| Filed:
|
September 25, 1997 |
| Current U.S. Class: |
261/94; 261/112.2; 366/337 |
| Intern'l Class: |
B01F 003/04; B01F 005/06 |
| Field of Search: |
366/181.5,336,337,340
48/189.4
261/94,95,112.2,DIG. 72
|
References Cited
U.S. Patent Documents
| 899898 | Sep., 1908 | Petersen | 261/94.
|
| 1293270 | Feb., 1919 | Webb | 261/95.
|
| 2055162 | Sep., 1936 | Weber | 261/94.
|
| 2571958 | Oct., 1951 | Slaughter et al. | 261/95.
|
| 2591497 | Apr., 1952 | Berl | 261/95.
|
| 2986379 | May., 1961 | Kramig, Jr. | 261/112.
|
| 3285587 | Nov., 1966 | Huber | 261/112.
|
| 3785620 | Jan., 1974 | Huber | 366/337.
|
| 3983190 | Sep., 1976 | Norback | 261/112.
|
| 4290980 | Sep., 1981 | Pikon et al. | 261/94.
|
| 4310475 | Jan., 1982 | Leva | 261/94.
|
| 4541967 | Sep., 1985 | Masaki.
| |
| 4919541 | Apr., 1990 | Grosz-Roell et al. | 366/337.
|
| 5320428 | Jun., 1994 | Straiff.
| |
| 5709468 | Jan., 1998 | Woerheide et al.
| |
| 5749651 | May., 1998 | Huttenhofer et al.
| |
| Foreign Patent Documents |
| 0 361 225 | Apr., 1990 | EP.
| |
| 209 681 | May., 1909 | DE.
| |
| 161 066 | Sep., 1984 | DE.
| |
| 1 560 305 | Apr., 1990 | SU.
| |
| 02086527 | Apr., 1990 | SU.
| |
| 91/16970 | Nov., 1991 | WO.
| |
Primary Examiner: Cooley; Charles E.
Attorney, Agent or Firm: Shook, Hardy & Bacon L.L.P.
Claims
We claim:
1. A structured packing bed for positioning in a column having a
longitudinal axis, the bed comprising:
a plurality of bricks, each of said bricks including a plurality of
corrugated plates disposed in parallel relation with corrugations in
adjacent plates being disposed in criss-crossing relationship, said plates
having opposed ends which form end surfaces of the bricks, at least some
of said bricks having at least one of said end surfaces disposed at an
angle within a range of 15 to 45 degrees to the column longitudinal axis
and engaging in a parallel fashion the angled end surface of an adjacent
brick.
2. The packing bed of claim 1, wherein at least one of said bricks has both
of said end surfaces angled with respect to the column longitudinal axis.
3. The packing bed of claim 2, wherein both of said end surfaces of said at
least one brick are generally planar and angled towards one another such
that said at least one brick in vertical cross section has a generally
trapezoidal shape.
4. The packing bed of claim 2, wherein both of said end surfaces of said at
least one brick are generally planar and parallel to one another such that
said at least one brick in vertical cross section has a generally
parallelogram shape.
5. The packing bed of claim 1, wherein said angle of said at least one end
surface to the column axis is either approximately 30 degrees or
approximately 45 degrees.
6. A structured packing bed for positioning in a column having a
longitudinal axis, the column adapted to have liquid generally flowing
downwardly in the column and vapor generally flowing upwardly in the
column, the bed comprising:
at least two bricks arranged end to end, each said brick including a
plurality of plates disposed in parallel relation and having corrugations
formed therein; and
means associated with said bricks to aid transfer of liquid from one brick
to another and to prevent vapor from flowing directly upward between said
bricks,
wherein said corrugations of said bricks form openings along end surfaces
of said bricks and said transfer means includes the positioning of at
least some of said openings of one brick above the openings of a
horizontally adjacent brick.
7. A structured packing bed for positioning in a column having a
longitudinal axis, the bed comprising:
a plurality of bricks, each of said bricks including a plurality of
corrugated plates disposed in parallel relation and having opposed ends
forming end surfaces of the bricks, at least some of said bricks having at
least one of said end surfaces disposed at an angle to the column
longitudinal axis and engaging in a parallel fashion the angled end
surface of an adjacent brick,
wherein at least one of said bricks has both of said opposite first and
second end surfaces angled with respect to the column longitudinal axis,
and
wherein both of said end surfaces of said at least one brick are generally
planar and angled towards one another such that said brick in vertical
cross section has a generally trapezoidal shape.
8. The structured packing bed of claim 7, including liquid and vapor flow
openings at said end surfaces and formed by corrugations in said plates,
and wherein liquid, when present in the packing bed, is able to flow
vertically downwardly from the openings in said angled end surface of said
at least one brick into underlying openings in said angled end surface of
the adjacent brick.
9. At least one structured packing bed positioned within an exchange column
having a longitudinal axis, the bed comprising:
a plurality of bricks, each of said bricks including a plurality of plates
disposed in parallel relation and having corrugations formed therein, at
least some of said bricks having at least one end surface disposed at an
angle to the column longitudinal axis and engaging in a parallel fashion
the angled end surface of an adjacent brick,
wherein said corrugations form openings at the angled end surfaces and
liquid, when present in the packing bed, is able to flow vertically
downwardly from the openings in the angled end surface of each said brick
into underlying openings in said angled end surface of the adjacent
bricks.
10. The structured packing bed of claim 9, where in the corrugations of
each plate are disposed in crisscrossing relationship to corrugations of
adjacent plates.
11. The structured packing bed of claim 9, wherein said bricks have
generally vertical sides.
12. The structured packing bed of claim 11, wherein said bricks have
generally horizontal upper and lower surfaces.
13. The structured packing bed of claim 12, wherein said column
longitudinal axis is generally vertical.
14. The structured packing bed of claim 9, wherein said bricks are
positioned in a plurality of side by side rows, with the bricks in each
row being positioned end to end.
15. The structured packing bed of claim 14, including a second said
structured packing bed positioned vertically adjacent said at least one
structured packing bed, said rows of bricks in the at least one structured
packing bed extending in one direction and said rows of bricks in the
second structured packing bed extending in a different direction.
16. The structured packing bed of claim 15, wherein said angle of said end
surface to the column axis is within the range of approximately fifteen to
forty-five degrees.
17. The structured packing bed of claim 16, wherein said angle is
approximately 30 degrees or approximately 45 degrees and said column axis
extends generally vertically.
18. The structured packing bed of claim 14, wherein adjacent bricks are
positioned in an alternating right side up, upside down orientation within
each row.
19. The structured packing bed of claim 18, wherein adjacent bricks are
positioned in an alternating right side up, upside down orientation across
adjacent rows.
Description
BACKGROUND OF THE INVENTION
This invention relates to mass transfer devices for an exchange column and,
more particularly, to structured packing elements used for facilitating
mass transfer between fluid streams flowing within the column.
In various types of exchange columns, gas and liquid streams or two liquid
streams are contacted with one another to effect mass transfer between the
fluids. In many instances, structured packing elements formed of
corrugated plates are used to facilitate contact between the fluids for
enhanced mass transfer. These plates are typically positioned parallel to
the column axis and are arranged so that the corrugations of each plate
are disposed at an angle to the column axis. The corrugations of each
plate also extend at an angle to and are in contact with the corrugations
of adjacent plates to create inclined flow channels for the fluid streams.
Typically, the vertically extending plates fill the horizontal cross
section of the column and multiple layers of these plates may be used to
fill the desired vertical dimension within the column. If multiple layer
of plates are used, the plates in adjacent layers are rotated with respect
to one another to enhance the radial or lateral distribution and mixing of
the fluid streams.
To facilitate fabrication and installation of the corrugated plates
described above in exchange columns, particularly those columns having a
large diameter, bundles or "bricks" of plates are assembled together and
are positioned in side by side relationship to fill the horizontal cross
section of the column. The plates in each brick are held together in
various fashions such as by mesh banding around the plates, welding, or
pins inserted through the plates. The bricks are generally six-sided and
have differing shapes dictated by the size of the brick in relation to the
cross-sectional dimension of the column, the shape of the column and the
intended placement position within the column. Those bricks positioned
centrally within the cross section of the column will normally have a
cubic or rectangular shape while those bricks adjacent the column wall
will be shaped to conform to the shape of the column wall. For example, in
cylindrical columns, the outer perimeter bricks will have at least one
curved end or side to conform to the curved shape of the column. The
curved end of the brick is formed by using plates with progressively
shorter widths. In some bricks, one end of the plates lies in a common
vertical plane while the opposite end of the plates forms a curve to
approximate the shape of the column wall. In other bricks, both ends form
curved surfaces.
While the use of the packing brick construction has greatly eased the
fabrication and installation of corrugated plates in exchange columns, the
separation efficiency of these plates may suffer because of less than
desired communication of liquid streams between the ends of adjacent
bricks. Efficiency may further suffer as a result of vapor streams
bypassing the desired flow paths and passing upwardly along the vertical
gaps which may form between the vertical ends of adjacent bricks. A need
has thus developed for a structured packing brick having increased
separation efficiency.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to provide a packing
brick construction which reduces the efficiency losses associated with
utilization of such packing bricks.
Another object of this invention is to provide a packing bed constructed of
individual packing bricks which allow ease of installation while at the
same time maintaining the overall efficiency of the column.
A further object of this invention is to provide a shape for a packing
brick which allows increased transfer of liquid between horizontally
adjacent bricks, and further diverts the path of upwardly flowing vapor
between adjacent bricks, such that contact between vapor and liquid is
increased.
Accordingly, the present invention provides for a structured packing brick
for positioning in a column having a longitudinal axis. The brick includes
a plurality of corrugated plates disposed in parallel relation. The
plurality of plates defines at least one end surface for engaging the end
surface of a horizontally adjacent brick. The end surface of the brick is
disposed at an angle with respect to the column longitudinal axis.
Additional objects, advantages, and novel features of the invention will be
set forth in part in the description which follows, and in part will
become apparent to those skilled in the art upon examination of the
following, or may be learned by practice of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
In the accompanying drawings which form a part of this specification and
are to be read in conjunction therewith and in which like reference
numerals are used to indicate like parts in the various views:
FIG. 1 is a fragmentary side elevation view of a mass transfer column
utilizing the packing bricks of the present invention, parts being broken
away and shown in cross section to show details of construction;
FIG. 2 is a top plan view taken in horizontal cross section along line 2--2
of FIG. 1 showing generally a packing bed layer composed of the packing
bricks of the present invention, with the lower end edges of the bricks
shown in broken lines, and portions of the layer broken away to show the
details of construction of a lower layer of packing bricks;
FIG. 3 is a fragmentary side elevation view taken in vertical cross section
along line 3--3 of FIG. 2 showing multiple packing bed layers, each of the
layers composed of the inventive packing brick;
FIG. 4 is a top perspective view of a single inventive packing brick, one
plate of the brick packing broken away to show the crisscrossing
orientation of the corrugations in adjacent plates;
FIG. 5 is a top perspective of an alternative embodiment of the inventive
packing brick, one plate of the brick partially broken away to show the
crisscrossing corrugation orientation;
FIG. 6 is a cross-sectional view similar to FIG. 3, but showing the
orientation and positioning of the alternative embodiment packing brick of
FIG. 5 positioned within a layer of a column; and
FIG. 7 is a top plan view similar to FIG. 2, but showing the alternative
packing brick of FIG. 5 positioned in a layer with the lower edges of the
bricks shown in broken lines, and a portion broken away to show the
orientation of the lower layer of bricks.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to the drawings in greater detail, and initially to FIG. 1, an
exchange column designated generally by the numeral 10 is shown. Column 10
is a generally cylindrical structure with a vertical longitudinal axis 12.
Generally, during a mass transfer or heat exchange process, one or more
liquid streams flow downwardly and one or more vapor streams flow upwardly
through the column as indicated in FIG. 1. Positioned within column 10 is
a structured packing bed 14 which provides surfaces upon which an exchange
can take place between the downwardly flowing liquid and the upwardly
flowing vapor. Packing bed 14 is constructed of a plurality of vertically
disposed layers 16. Each layer 16 is in turn comprised of a plurality of
structured packing bricks 18.
With reference to FIG. 4, each brick 18 includes a plurality of generally
parallel, vertically disposed plates 20. In particular, each plate 20 is
generally parallel to the longitudinal axis 12 of column 10. Each plate 20
further has a plurality of corrugations or folds 22 formed therein. The
corrugations 22 of each plate are generally at an angle with respect to
axis 12. Further, as best shown in FIG. 4 in the broken away portion, the
corrugations of each plate 20 contact and are in a crisscrossing
relationship to the corrugations of an adjacent plate. Plates 20 of bricks
18 are held together by any suitable means, such as pins, bolts, rivets,
welding, soldering, or mesh banding as is well-known in the art. Further,
plates 20 can be made of any suitable material such as sheet metal,
ceramics, or polymers that can withstand the conditions within the column
and is compatible with the fluid streams. Each brick 18 includes generally
horizontal upper and lower surfaces 24 and 26, generally vertical side
surfaces 28 and 30, and end surfaces 32 and 34. Depending upon the
intended placement of brick 18, one or both end surfaces 32 and 34 are
angled generally inwardly from a lower edge 36 toward an upper edge 38. As
best shown in FIG. 3, the angled end surfaces 32 and 34 generally result
in bricks 18 having a trapezoidal shape in vertical cross section. Each
end surface 32 and 34 has corrugation end openings 40 formed thereon. In
particular, openings 40 are where at least some of the corrugations on
plates 20 begin or end.
With reference to FIGS. 2 and 3, the construction of packing bed 14
utilizing bricks 18 will be described. It is advantageous to position
bricks 18 in layers 16. Each layer 16 is made of side-by-side rows 42 of
bricks 18, as shown in FIG. 2. Each row 42 is made of bricks 18 disposed
in end-to-end fashion, as best shown in FIG. 3. In particular, the angled
end surfaces 32 and 34 of each brick 18 engage the angled end surfaces 32
and 34 of an adjacent brick, which is positioned in an upside down
orientation. Therefore, in each row 42 bricks 18 are positioned in an
end-to-end fashion and in an alternating right side up, upside down
orientation. This orientation permits mating and helps ensure close
contact between the overlapping angled end surfaces 32, 34 of adjacent
bricks. Bricks in adjacent rows are also positioned in an alternating
right side up, upside down orientation, as best shown in FIG. 2, so that
the alternating orientation is formed within each row and across adjacent
rows. This pattern helps to facilitate more uniform radial distribution of
the downward flowing liquid. The bricks 18 within a layer 16 adjacent the
curved outer shell of column 10 can be specially configured so that the
entire cross section of the column is covered by bricks 18, as is shown in
FIG. 2.
With reference to FIGS. 2 and 3, vertically adjacent layers 16 are rotated
with respect to one another by an appropriate angle, which in this case is
90 degrees but could be other angles if desired. In particular, with
reference to FIG. 2, layer 16a has plates 20 of each brick 18 extending in
the same direction. Layer 16b which is below layer 16a has each of its
plates in its bricks extending in a direction that is 90 degrees from the
direction of the plates in layer 16a. Therefore, the layers above and
below each layer 16 are rotated in this fashion to create an alternating
flow pattern.
With reference to FIG. 3, the end-to-end arrangement with the angled end
surfaces 32 and 34 results in openings 40 on an angled end surface of one
block being vertically above openings 40 on an adjacent block. This
arrangement allows the downwardly flowing fluid to more easily transfer to
adjacent blocks due to gravity. Additionally, because the angled surfaces
32 and 34 are at an angle a to the longitudinal axis 12 of column 10,
vapor flowing upwardly within column 10 is diverted from flowing directly
upwardly due to the angled end surfaces.
The present invention involves the discovery that the vertical end surfaces
of prior art bricks allowed vapor to take the path of least resistance
(parallel to axis 12) between adjacent bricks. Further, the vertical end
surfaces of prior art blocks resulted in liquid channeling between
adjacent bricks. Therefore, the present invention of bricks 18 with
overlapping angled end surfaces 32, 34 results in assured fluid transfer
between horizontally adjacent bricks in a layer, and helps prevents
channeling of the fluid between adjacent bricks. Further, because any
vapor that flows between adjacent bricks now must flow at an angle to the
longitudinal axis 12 of the column, the contact of the vapor with liquid
is increased. Thus, the use of bricks with angled end surfaces positioned
in the alternating fashion shown in FIG. 3 helps increase the efficiency
of the column.
It has been found that to allow ease of installation of bricks 18, the
angle a of the end surfaces 32, 34 with respect to axis 12 should be in
the range of approximately 15 to 45 degrees. Larger angles, although more
difficult to install, are also suitable and can provide greater increases
in efficiency because of increased overlapping of the end surfaces.
Smaller angles, although easier to install, may be less preferred because
of smaller increases in efficiency due to the smaller amount of
overlapping of the end surfaces.
The angle of inclination of the corrugations in plates 20 may also limit
the increases in efficiencies obtainable with larger angles .alpha.. In
general, the corrugation angle will be in the range of approximately 15 to
45 degrees, and will typically be either 30 or 45 degrees. The upper end
of the range for angle .alpha. will thus normally not exceed the
corrugation angle. It will, of course, be appreciated that the angle
.alpha. may exceed the corrugation angle in particular applications and
still fall within the scope of the present invention.
With reference to FIGS. 5-7, an alternative brick configuration 44 is
shown. As with brick 18, brick 44 is made of a plurality of plates 20
having corrugations 22. Further, the corrugations of each plate are
arranged in a crisscrossing manner to corrugations of adjacent plates, as
shown in the broken away portion of FIG. 5. Each brick 44 has upper and
lower surfaces 24 and 26, respectively, and side surfaces 28 and 30. Brick
44 further has angled end surfaces 46 and 48. End surfaces 46 and 48 of
brick 44 are angled with respect to longitudinal axis 12, and are parallel
to one another. This is in contrast to angled end surfaces 32, 34 of
bricks 18, which are angled toward one another. In particular, a vertical
cross section of brick 44 generally forms a parallelogram, as best shown
in FIG. 6. End surfaces 46, 48 also have corrugation openings 40 formed
thereon.
As best shown in FIGS. 6 and 7, bricks 44 are also disposed in layers 16
which are made of a plurality of side-by-side rows 42. Each row 42 consist
of a plurality of bricks 44 disposed in end-to-end fashion such that the
angled end surfaces 46, 48 of adjacent bricks contact one another. As best
shown in FIG. 5, each of the end surfaces 46, 48 of bricks 44 are at an
angle .beta. with respect to the longitudinal axis 12 of column 10.
Openings 40 of an end surface 46 of one brick are disposed above openings
40 of an end surface 48 of an adjacent brick. Therefore, again, this
structure allows liquid flowing downwardly within column 10 to be
transferred from one brick to an adjacent brick within a layer 16. Bricks
18 in adjacent rows are rotated 180 degrees with respect to each other, as
best shown in FIG. 7, to provide more uniform radial flow of liquid. As
with bricks 18, the bricks 44 in a layer that are adjacent the outer
circumference of column 10 can be specially configured so that the entire
cross section of column 10 is covered with bricks 44, as is best shown in
FIG. 7. Also, as with bricks 18, adjacent layers 16 of bricks 44 are
rotated with respect to one another, as best shown in FIG. 7. In
particular, a lower layer 16b is rotated 90 degrees with respect to upper
layer 16a.
As with bricks 18, the plates of bricks 44 can be held together in any
suitable fashion, such as pins, bolts, mesh strapping, welding or rivets,
as is known in the art. Also, as with bricks 18, overlapping angled end
surfaces 46, 48 of bricks 44 allow liquid transfer between and close
nesting of adjacent bricks, and further prevent channeling of fluid
between the bricks as often happened with vertically oriented end surfaces
of prior art bricks. Further, the overlapping angled mating between
adjacent bricks prevents the vapor from flowing directly upwardly within
the column between adjacent bricks, and thus increases the possibility of
contact with downwardly flowing liquid. Again, the structure of brick 44
with its angled end surfaces increases the efficiency and decreases the
HETP of the column.
As with brick 18, the preferred angle .beta. of end surfaces 46, 48 with
respect to longitudinal axis 12 is within the range of approximately 15 to
45 degrees and may be limited by the angle of corrugations in plates 20.
This range allows ease of fabrication and assembly of bricks 44 within the
column. Larger angles may also be used but are more difficult to install.
Smaller angles may also be used but have less effect on efficiency.
It will be appreciated that the improved efficiencies possible with the
bricks of the present invention result from the overlapping inclined end
surfaces which permit vertical transfer of liquid under the influence of
gravity between horizontally adjacent bricks. These inclined surfaces also
facilitate the placement of the bricks in close nested contact with each
other, thereby eliminating the vertical gaps that may form between
conventional bricks and permit undesired vapor or liquid flow along the
gaps. Although the invention has been described with respect to the
illustrated trapezoid and parallelogram shaped bricks, overlapping
inclined end surfaces can be presented by other geometric configurations.
These alternative configurations are encompassed by and are within the
scope of the present invention.
From the foregoing, it will be seen that this invention is one well-adapted
to attain all the ends and objects herein-above set forth together with
other advantages which are inherent to the structure. It will be
understood that certain features and subcombinations are of utility and
may be employed without reference to other features and subcombinations.
This is contemplated by and is within the scope of the claims. Since many
possible embodiments may be made of the invention without departing from
the scope thereof, it is to be understood that all matter herein set forth
or shown in the accompanying drawings is to be interpreted as illustrative
and not in a limiting sense.
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